Surface State Transport and Ambipolar Electric Field Effect in Bi2Se3 Nanodevices

Electronic transport experiments involving the topologically protected states found at the surface of Bi[subscript 2]Se[subscript 3] and other topological insulators require fine control over carrier density, which is challenging with existing bulk-doped material. Here we report on electronic transp...

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Bibliographic Details
Main Authors: Steinberg, Hadar (Contributor), Gardner, Dillon Richard (Contributor), Lee, Young S. (Contributor), Jarillo-Herrero, Pablo (Contributor)
Other Authors: Massachusetts Institute of Technology. Department of Physics (Contributor)
Format: Article
Language:English
Published: American Chemical Society, 2011-03-23T13:13:27Z.
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Summary:Electronic transport experiments involving the topologically protected states found at the surface of Bi[subscript 2]Se[subscript 3] and other topological insulators require fine control over carrier density, which is challenging with existing bulk-doped material. Here we report on electronic transport measurements on thin (<100 nm) Bi[subscript 2]Se[subscript 3] devices and show that the density of the surface states can be modulated via the electric field effect by using a top-gate with a high-k dielectric insulator. The conductance dependence on geometry, gate voltage, and temperature all indicate that transport is governed by parallel surface and bulk contributions. Moreover, the conductance dependence on top-gate voltage is ambipolar, consistent with tuning between electrons and hole carriers at the surface.